Measuring transducer of vibration-type as well as measuring system formed therewith

ABSTRACT

A measuring transducer comprises a measuring tube having an inlet-side tube end and an outlet-side tube end, a tube wall having a predetermined wall thickness and a lumen surrounded by the tube wall and extending between the first and second tube end, a support element, which with a support end is mechanically connected with the tube end and with a support end is mechanically connected with the tube end, as well as, laterally spaced from the measuring tube, a support element, which with a support end is mechanically coupled with the support end and with a support end is mechanically coupled with the support end. The measuring tube is adapted to guide a flowing medium in its lumen and caused to oscillate about a static resting position for producing Coriolis forces. An oscillation exciter as well as at least one oscillation sensor. The measuring transducer has a wanted mode having a resonant frequency, in which the measuring tube can execute wanted oscillations around its static resting position suitable for producing Coriolis forces and having a wanted frequency corresponding to the resonant frequency of the wanted mode. The oscillation exciter is placed externally on the measuring tube and one exciter component is placed on the support element, is, furthermore, adapted to excite the wanted oscillations of the measuring tube, and the oscillation sensor, of which one sensor component is placed externally on the measuring tube and one sensor component is placed on the support element, is adapted to register movements of the measuring tube relative to the support element and to convert such into an oscillatory signal representing oscillations of the measuring tube.

TECHNICAL FIELD

The invention relates to a measuring transducer of vibration-type,especially one suitable for a Coriolis mass flow measuring device, aswell as to a measuring system formed therewith, especially a Coriolismass flow measuring device.

BACKGROUND DISCUSSION

Used in industrial measurements technology, especially also inconnection with the control and monitoring of automated manufacturingprocesses, for ascertaining mass flow rates and/or mass flows of media,for example, liquids and/or gases, flowing in a process line, forexample, a pipeline, are often measuring systems, which, by means of ameasuring transducer of vibration-type and a measuring- and operatingelectronics connected thereto and accommodated most often in a separateelectronics housing, induce Coriolis forces in the flowing medium and,derived from these forces, generate measured values representing themass flow, respectively the mass flow rate.

Such measuring systems—most often embodied as in-line measuring devicesinserted directly into the course of the process line and, consequently,having a nominal diameter corresponding to a nominal diameter of thepipeline have been known for a long time and have proved themselves inindustrial use. Examples of measuring transducers of the vibration-type,respectively measuring systems formed therewith, are described e.g. inUSA 2003/0084559, USA 2003/0131669, US A 2005/0139015, U.S. Pat. No.4,655,089, U.S. Pat. No. 4,801,897, U.S. Pat. No. 4,831,885, US A5,024,104, U.S. Pat. No. 5,129,263, U.S. Pat. No. 5,287,754, U.S. Pat.No. 5,381,697, U.S. Pat. No. 5,531,126, U.S. Pat. No. 5,705,754, U.S.Pat. No. 5,736,653, U.S. Pat. No. 5,804,742, U.S. Pat. No. 6,006,609, USA 6,047,457, U.S. Pat. No. 6,082,202, U.S. Pat. No. B6,223,605, U.S.Pat. No. 6,311,136, U.S. Pat. No. B6,360,614, U.S. Pat. No. B6,516,674,U.S. Pat. No. B6,840,109, U.S. Pat. No. B6,851,323, U.S. Pat. No.B7,077,014 or published international application WO A 00/02020. Showntherein, in each case, is a measuring transducer having at least onemeasuring tube, which is symmetric relative to a symmetry center point.The measuring tube has a tube wall of a predetermined wall thickness andcomposed, for example, of a titanium-, zirconium- and/or tantalum alloyor a stainless steel, and a lumen extending between inlet-side andoutlet-side, tube ends of the measuring tube and surrounded by the tubewall.

The, for example, S-, respectively Z-shaped, or straight, measuring tubeis held oscillatably in an outer support element, for example, ofstainless steel, formed, for example, also as a measuring transducerhousing jacketing the measuring tube and, consequently, protecting themeasuring tube and/or as a support tube at least jacketing the measuringtube. The measuring tube is solidly connected only with its inlet-sidetube end with a corresponding inlet-side support end of the outersupport element and with its outlet-side tube end with a correspondingoutlet-side support end of the outer support element, but is otherwiselaterally spaced from the outer support element. The outer supportelement is, furthermore, adapted, directly, namely via, in each case, aconnecting flange provided on each of its two support ends, to bemechanically connected with, in each case, a corresponding line segmentof the pipeline, and, thus, to hold the total measuring transducer inthe pipeline, respectively to absorb forces introduced from thepipeline. The measuring tube, in turn, opens with each of its two tubeends into the respectively corresponding connecting flanges for thepurpose of forming a flow path connecting the two line segments forflow, namely permitting traversing flow from one line segment throughthe measuring tube to the other line segment.

The at least one measuring tube is, furthermore, adapted, in operationof the measuring system, to guide a flowing medium, for example, a gasand/or a liquid, in its lumen, so as to form with respective lumen ofthe connected pipeline the mentioned flow path, and during that to becaused to oscillate about its static resting position for producing asmeasurable effect Coriolis forces usable for measuring the mass flowrate, and, consequently, the mass flow. Serving as wanted oscillations,namely oscillations of the measuring tube suitable for producingCoriolis forces, are usually oscillations of a natural mode ofoscillation inherent to the measuring transducer, the so-called drive,or also wanted, mode, which are excited with an instantaneous resonantfrequency of such mode of oscillation, for example, also withpractically constant oscillation amplitude. The wanted oscillationsgenerate, as a result of the medium flowing through the measuring tubeoscillating in the wanted mode, Coriolis forces, which, in turn, bringabout Coriolis oscillations, namely additional oscillatory movements ofthe measuring tube in the so-called Coriolis mode synchronous with theoscillatory movements of the measuring tube in the wanted mode and,consequently, superimposed thereon. Due to such superimposing of wanted-and Coriolis modes, the oscillations of the vibrating measuring tuberegistered by means of the sensor arrangements at the inlet side and atthe outlet-side have a measurable phase difference dependent also on themass flow rate.

As already indicated, selected as excitation- or wanted frequency,namely as frequency for the excited wanted oscillations, is usually aninstantaneous natural resonant frequency of the oscillation form servingas wanted mode. The wanted mode is, in such case, also so selected thatthe resonant frequency is, especially, also dependent on theinstantaneous density of the medium. As a result of this, the wantedfrequency is variable within a wanted frequency interval correspondingto a fluctuation of a density of the medium flowing in the lumen of themeasuring tube, whereby by means of market-usual Coriolis mass flowmeters besides the mass flow supplementally also the densities offlowing media can be measured. Furthermore, it is also possible, suchas, among other things, shown in the above mentioned U.S. Pat. No.6,006,609 or U.S. Pat. No. 5,531,126, by means of measuring transducersof the type being discussed directly to measure a viscosity of theflowing medium, for example, based on an excitation power required forexciting, respectively maintaining, the wanted oscillations damped bythe medium.

As, among other things, also shown in US-A 2005/0139015, US-A2003/0131669, U.S. Pat. No. 7,077,014, U.S. Pat. No. 6,840,109, U.S.Pat. No. 6,516,674, U.S. Pat. No. 6,082,202, U.S. Pat. No. 6,006,609,U.S. Pat. No. 5,531,126, U.S. Pat. No. 5,381,697, U.S. Pat. No.5,287,754 or WO-A 00/02020, measuring transducers of the type beingdiscussed can be formed quite easily by means of only a single measuringtube in such a manner that the particular measuring transducer —, forinstance, in contrast to that shown in U.S. Pat. No. 4,655,089—has,except for the mentioned measuring tube, no (other) tube adapted toguide a medium flowing in a lumen and, during that, to be caused tooscillate about a static resting position. As shown in the abovementioned U.S. Pat. No. 7,077,014, in the case of measuring transducerswith a single, point symmetric, measuring tube, among other things, alsosuch an oscillatory mode can be actively excited as wanted mode,consequently such oscillations can be selected as wanted oscillations,in the case of which the measuring tube has, in each case, fouroscillation nodes, consequently exactly three oscillation antinodes,wherein—at least in the case of ideally uniformly formed measuring tubewith homogeneous wall thickness and homogeneous cross section,consequently with an equally ideally homogeneous stiffness- and massdistribution—the four oscillation nodes lie in at least one imaginaryprojection plane of the measuring transducer on an imaginary oscillationaxis imaginarily connecting the inlet-side and the outlet-side tube endswith one another, respectively such an imaginary projection plane isinside of the measuring transducer. In the case of measuring transducerswith straight measuring tube, the projection plane correspondspractically to a cutting plane cutting the measuring tube imaginarilyinto two halves, consequently an imaginary bend line representing thewanted oscillations of the measuring tube is coplanar with thisprojection plane.

Such measuring transducers offered most often with a nominal diameterlying in the range between 0.5 mm and 100 mm and having only a singlemeasuring tube, consequently with only a single tube, through whichmedium flows, are usually—, for instance, also for preventing,respectively minimizing, undesired, not least of all also transverse,forces dependent on the density of the medium to be measured,respectively, disturbances of the measuring effect associatedtherewith—supplementally to the aforementioned outer support element,equipped with an additional, inner, support element, which isoscillatably coupled, namely affixed to the measuring tube only with aninlet-side support end and with an outlet-side support end spacedtherefrom, consequently is mechanically coupled with its first supportend also with the first support end of the outer support element,respectively with its second support end with the second support end ofthe outer support element. The inner support element is, in such case,furthermore, so embodied and arranged that it is spaced laterally fromthe measuring tube, as well as also from the outer support element, andthat both the inlet-side as well as also the outlet-side support ends ofthe inner support element are, in each case, spaced from both of thesupport ends of the outer support element. In the case of such anarrangement of the inner support element on the measuring tube, thereextends both between the inlet-side support ends of the two supportelements as well as also between the outlet-side support ends of the twosupport elements, in each case, a free, for example, also straight, tubesegment of the measuring tube acting as a spring element between bothsupport elements and allowing movements of the respectively associatedsupport ends of the inner support element relative to the support endsof the outer support element. As a result of this, the measuringtransducer enjoys also an oscillatory mode exhibiting most often aresonant frequency different from the wanted frequency and characterizedby movement of the entire inner support element relative to the outersupport element, in such a manner that also the two support ends of theinner support element are moved relative to the two support ends of theouter support element. In other words, conventional measuringtransducers with only a single measuring tube have most often, formed bymeans of the measuring tube and the inner support element held thereto,an inner part, which is held —, for example, also exclusively—by meansof the two free tube segments in the outer support element, and, indeed,in a manner enabling oscillations of the inner part relative to theouter support element. The inner support element composed most often ofa steel, for example, a stainless steel or a free-machining steel, isusually embodied as a hollow cylinder at least sectionally enveloping,for example, also coaxial with, the measuring tube or, such as shown,among other things, in the above mentioned U.S. Pat. No. 7,077,014 orU.S. Pat. No. 5,287,754, for instance, also as a plate, frame or box,and has additionally also a mass, which is most often greater than amass of the single measuring tube. As shown, among other things, in theabove mentioned U.S. Pat. No. 5,531,126, the inner support element can,however, also be formed by means of a blind tube extending parallel tothe measuring tube and, in given cases, also essentially equallyconstructed thereto as regards material and geometry.

For active exciting of the wanted oscillations, measuring transducers ofthe vibration-type have, additionally, at least one electro-mechanicaloscillation exciter acting most often centrally on the measuring tubeand driven during operation by an electrical driver signal generated bythe mentioned driver electronics and correspondingly conditioned to havea signal frequency corresponding to the wanted frequency, e.g. with acontrolled electrical current. The oscillation exciter, usually embodiedas a type of oscillation coil and, consequently, being ofelectro-dynamic type, includes most often a first exciter componentaffixed externally on the measuring tube, for example, mounted on itstube wall and formed by means of a rod-shaped, permanent magnet, as wellas an oppositely placed, second exciter component interacting with thefirst exciter component. The oscillation exciter serves to convert anelectrical power fed by means of the driver signal into a correspondingmechanical power and thereby to generate the exciter forces effectingthe wanted oscillations of the measuring tube. In the case of theaforementioned measuring transducers with only a single tube, the secondexciter component, which is most often formed by means of a cylindricalcoil and, consequently, connected with electrical connecting lines, isusually placed on the inner support element, so that the oscillationexciter acts differentially on support element and measuring tube, sothat the inner support element can, during operation, executeoscillations, which are embodied opposite-equally relative to those ofthe measuring tube, thus with equal frequency and opposite phase. As,among other things, provided in the above mentioned U.S. Pat. No.5,531,126, the oscillation exciter e.g. in the case of conventionalmeasuring transducers of vibration-type can, however, also be soembodied that it acts differentially on the inner and outer supportelements, and, consequently, excites the wanted oscillations of themeasuring tube indirectly.

For registering inlet-side and outlet-side oscillations of the measuringtube, not least of all also those with the wanted frequency, measuringtransducers of the type being discussed have, furthermore, twooscillation sensors, which are, most often, equally constructed. Thesework usually according to the same principle of action as theoscillation exciter. Of these oscillation sensors, an inlet-sideoscillation sensor is located between the oscillation exciter and theinlet-side tube end of the measuring tube and an outlet-side oscillationsensor between the oscillation exciter and an outlet-side tube end ofthe measuring tube. Each of the oscillation sensors, for example,electro-dynamic, oscillation sensors, serves to convert oscillatorymovements of the measuring tube into an oscillatory signal representingoscillations of the measuring tube. For example, the oscillatory signalcan be a measurement voltage dependent on the wanted frequency as wellas an amplitude of the oscillatory movements. For such purpose, each ofthe oscillation sensors includes a first sensor component affixedexternally on the measuring tube, for example, connected with its tubewall by material bonding and/or formed by means of a permanent magnet,as well as a second sensor component placed opposite the first sensorcomponent and interacting with the first sensor component. In the caseof the aforementioned measuring transducers with only a single tube, thesecond sensor component, which is most often formed by means of acylindrical coil and is, consequently, connected with electricalconnecting lines, is usually placed on the inner support element, insuch a manner that each of the oscillation sensors differentiallyregisters movements of the measuring tube relative to the second supportelement.

In the case of measuring transducers of the type being discussed, it is,such as, among other things, also mentioned in U.S. Pat. No. 6,047,457or US-A 2003/0084559, additionally usual to hold the exciter- or sensorcomponent affixed to the measuring tube, in each case, to an extra ring-or annular washer shaped, metal securement element, which is applied onthe particular measuring tube and which solidly clamps around themeasuring tube, in each case, essentially along one of its imaginary,circularly shaped, peripheral lines. The securement element can beaffixed to the measuring tube, for example, by material bonding, forinstance by soldering or brazing, and/or by force interlocking, e.g.frictional interlocking, for instance, by pressing externally, byhydraulic pressing or rolling from within the measuring tube or bythermal shrinking, for example, also in such a manner that thesecurement element is subjected durably to elastic or mixed plastic,elastic deformations and, as a result, is permanently radiallyprestressed relative to the measuring tube.

As discussed, among other things, also in the above mentioned WO-A00/02020, a disadvantage of measuring transducers with only a singlemeasuring tube is that the measuring transducers, in comparison withmeasuring transducers with two measuring tubes in the case of equalnominal diameter and comparable measuring tube geometry, most often havea significantly lesser sensitivity to the mass flow rate, in such amanner that, assuming, in each case, an optimal positioning of theoscillation sensors for best possible registering of the oscillations ofthe Coriolis mode, in the case of equal medium, equal mass flow rate aswell as, in each case, equal electrical excitation power fed into theoscillation exciter, an amplitude of the resulting oscillation fractionsof the Coriolis mode, consequently an amplitude of a signal component ofeach of the oscillation signals representing the Coriolis mode,respectively a signal-to-noise-ratio (S/N) of the signal components,defined by a ratio of an average signal power of the signal component ofthe respective oscillation signal representing the Coriolis mode to anaverage noise power of the respective oscillation signal, is regularlyless than in the case of measuring transducers with two measuring tubes.This is not least of all grounded in the fact that, in the case ofmeasuring transducers with only a single measuring tube, alone this isdirectly exposed to the Coriolis forces induced by the medium flowing,while there act on the inner support element coupled with the measuringtube no Coriolis forces induced therein, conversely, however,—causedalso by the principle of action applied in conventional measuringtransducers for exciting the wanted oscillations—always a mentionablepart of the mechanical excitation power provided by the oscillationexciter for generating Coriolis forces is converted into non-usableoscillations of the support element, and, consequently, is necessarilylost for producing the actual measuring effect; this, especially, alsoin the case of the indirect exciting of the oscillations proposed in theabove mentioned U.S. Pat. No. 5,531,126. In this connection, a furtherdisadvantage of such measuring transducers with only a single measuringtube compared with those with two measuring tubes is that the in anyevent low sensitivity to the mass flow rate additionally regularly alsohas a dependence on the density of the medium.

SUMMARY OF THE INVENTION

Starting from the above-described disadvantages arising especially inthe case of measuring transducers known from the state of the art withonly a single measuring tube, an object of the invention is so toimprove measuring transducers of the vibration-type that an efficiency,with which the wanted oscillations are excitable, consequently thesensitivity of such measuring transducers to the mass flow rate, isincreased.

For achieving the object, the invention resides in a measuringtransducer of the vibration-type, especially for a Coriolis mass flowmeasuring device, wherein the measuring transducer comprises:

a measuring tube having an inlet-side first tube end and an outlet-sidesecond tube end, for example, a measuring tube symmetric relative to asymmetry center point and/or curved in at least sectionally S,respectively Z, shape and/or an at least sectionally straight and/orsingle measuring tube, having a tube wall having a predetermined wallthickness and a lumen surrounded by the tube wall and extending betweenthe first and second tube ends, a first support element, e.g. an atleast sectionally cylindrical first support element and/or a firstsupport element embodied as a housing jacketing the measuring tube,wherein the first support element is with a first support end connectedmechanically, especially rigidly, with the first tube end of themeasuring tube and with a second support end connected mechanically,especially rigidly, with the second tube end of the measuring tube, asecond support element, e.g. one formed by means of a blind tubeconstructed equally to the measuring tube and/or extending at leastsectionally parallel to the measuring tube, wherein the second supportelement is laterally spaced from the measuring tube and is mechanicallycoupled with the first support element both with a first support end aswell as also with a second support end, an oscillation exciter, forexample, a single and/or electrodynamic oscillation exciter, as well asat least a first oscillation sensor, for example, an electrodynamic,first oscillation sensor. The measuring tube is adapted to guide in itslumen a flowing medium, for example, a gas and/or a liquid, and duringthat to be caused to oscillate about a static resting position forproducing Coriolis forces, wherein the measuring transducer has a wantedmode having a resonant frequency, namely an oscillatory mode, in whichthe measuring tube can execute wanted oscillations, namely oscillationsabout its static resting position suitable for producing Coriolis forcesand having a wanted frequency, namely a frequency corresponding to theresonant frequency of the wanted mode, for example, also in such amanner that the wanted oscillations of the measuring tube have fouroscillation nodes, consequently three oscillation antinodes, and whereinthe oscillation exciter is adapted to excite the wanted oscillations ofthe measuring tube. For such purpose, the oscillation exciter includes afirst exciter component affixed externally on the measuring tube, forexample, connected with its tube wall by material bonding and/or formedby means of a permanent magnet, as well as a second exciter componentmounted on the first support element, for example, a second excitercomponent placed on an inside of said support element facing themeasuring tube and/or formed by means of a cylindrical coil.Additionally, the first oscillation sensor of the measuring transducerof the invention is adapted to register movements of the measuring tuberelative to the second support element, for example, movements ofoscillations of the measuring tube with the wanted frequency, and toconvert such into a first oscillatory signal representing oscillationsof the measuring tube. For such purpose, the oscillation sensor includesa first sensor component affixed externally on the measuring tube, forexample, a first sensor component also connected with the tube wall bymaterial bonding and/or formed by means of a permanent magnet as well asa second sensor component mounted on the second support element, forexample, a second sensor component formed by means of a cylindricalcoil.

Moreover, the invention resides in a measuring system, especially formeasuring a mass flow rate and/or a mass flow of a medium flowing in apipeline, which measuring system comprises such a measuring transduceras well as a measuring- and operating electronics electrically connectedto the measuring transducer.

In a first embodiment of the invention, it is provided that themeasuring transducer, except for the oscillation exciter, has nooscillation exciter with an exciter component mounted on the firstsupport element and/or no oscillation exciter with an exciter componentmounted on the second support element.

In a second embodiment of the invention, it is provided that the firstsupport end of the second support element is mechanically connected,especially rigidly, with the first support end of the first supportelement and the second support end of the second support element ismechanically connected, especially rigidly, with the second support endof the first support element.

In a third embodiment of the invention, it is provided that the firstsupport element is formed by means of a hollow body, for example, an atleast sectionally cylindrical and/or tubular hollow body and/or a hollowbody at least partially enveloping both the measuring tube as well asalso the second support element.

In a fourth embodiment of the invention, it is provided that the firstsupport element has a lumen, through which both the measuring tube aswell as also the second support element extend.

In a fifth embodiment of the invention, it is provided that the firstsupport element has a first endpiece forming the first support end, asecond endpiece forming the second support end as well as anintermediate piece, for example, a cylindrical and/or tubularintermediate piece, extending between the two endpieces, for example,equally-constructed endpieces, for example, forming a hollow body atleast partially enveloping both the measuring tube as well as also thesecond support element.

In a sixth embodiment of the invention, it is provided that the firstsupport element has a maximum flexibility, which is less than a maximumflexibility of the measuring tube.

In a seventh embodiment of the invention, it is provided that the firstsupport element has a maximum flexibility, which is less than a maximumflexibility of the second support element.

In an eighth embodiment of the invention, it is provided that the firstsupport element is formed by means of a cylindrical tube having a tubewall and a lumen surrounded by the tube wall, for example, in such amanner that measuring tube and second support element are, in each case,arranged, at least partially, within a lumen of the tube, and/or that awall thickness of the tube wall of the tube forming the first supportelement is greater than the wall thickness of the tube wall of themeasuring tube, wherein a wall thickness of the tube wall of the tubeforming the first support element is greater than the wall thickness ofthe tube wall of the measuring tube, for example, in such a manner thatthe wall thickness of the tube wall of the tube forming the firstsupport element is more than twice as large as the wall thickness of thetube wall of the measuring tube, and/or that the wall thickness of thetube wall of the measuring tube is greater than 0.5 mm and less than 3mm and the wall thickness of the tube wall of the tube forming the firstsupport element is greater than 3 mm.

In a ninth embodiment of the invention, it is provided that themeasuring transducer, except for the measuring tube, has no tube, whichis adapted to guide a medium flowing in a lumen and during that to becaused to oscillate about a static resting position.

In a tenth embodiment of the invention, the first support end of thefirst support element has a connecting flange, into which the first tubeend of the measuring tube opens, and the second support end of the firstsupport element has a connecting flange (F#), into which the second tubeend of the measuring tube opens.

In an eleventh embodiment of the invention, the first support element isadapted to be inserted into the course of a pipeline, in such a mannerthat the lumen of the measuring tube communicates with a lumen of thepipeline to form a flow path.

In a twelfth embodiment of the invention, it is provided that theresonant frequency of the wanted mode depends on a density, for example,a time variable density, of the medium guided in the measuring tube.

In a thirteenth embodiment of the invention, the measuring transducerhas a plurality disturbance modes of first type having, in each case, aresonant frequency, namely oscillation modes, in which the first supportelement can, in each case, execute disturbing oscillations, namely, ineach case, oscillations effecting movements about its static restingposition relative to the measuring tube, as well as a plurality ofdisturbance modes of second type having, in each case, a resonantfrequency, namely oscillation modes, in which the second support elementcan, in each case, execute disturbing oscillations, namely, in eachcase, oscillations effecting movements about its static resting positionrelative to the measuring tube, and the measuring transducer is embodiedin such a manner that the resonant frequencies both of each of thedisturbance modes first type as well as also each of the disturbancemodes of second type, for example, deviate durably from the resonantfrequency of the wanted mode, for example, by, in each case, more than 2Hz. Especially, it is provided that the measuring transducer hassimilarly to the wanted mode a first disturbance mode of second type, inwhich the second support element can execute disturbing oscillations,which have exactly as many oscillation antinodes and oscillation nodesas one of the wanted oscillations of the measuring tube, and a resonantfrequency, which is less than the resonant frequency of the wanted mode.

In a 14^(th) embodiment of the invention, it is provided that the wantedfrequency is, for instance, as a result of time changes of a density ofa medium flowing in the lumen of the measuring tube, variable within awanted frequency interval, especially in such a manner that a first,wanted mode similar, disturbance mode of the measuring transducer, inwhich the second support element can execute disturbing oscillations,which have exactly as many oscillation antinodes and oscillation nodesas one of the wanted oscillations of the measuring tube and a resonantfrequency, which is less than, for example, by more than 2 Hz, a lowerinterval boundary of the wanted frequency interval defined by a smallestfrequency value not subceeded by the wanted frequency, and/or in such amanner that a second disturbance mode of the measuring transducer, inwhich the second support element can execute disturbing oscillations,which have one oscillatory antinode more, consequently one oscillationnode more than the wanted oscillations of the measuring tube, has aresonant frequency, which is greater, for example, by more than 2 Hz,than an upper interval boundary of the wanted frequency interval definedby a greatest frequency value not exceeded by the wanted frequency.

In a 15^(th) embodiment of the invention, it is provided that the wantedoscillations of the measuring tube have exactly four oscillation nodes,consequently exactly three oscillation antinodes. Furthermore, themeasuring transducer is so embodied that a resonant frequency of ameasuring transducer disturbance mode, in which the second supportelement can execute disturbing oscillations, which have one oscillatoryantinode less, consequently one oscillation node less, than the wantedoscillations of the measuring tube, is less, for example, by more than 2Hz, than a lower interval boundary of a wanted frequency interval,within which the wanted frequency is variable, for instance, as a resultof time changes of a density of a medium flowing in the lumen of themeasuring tube.

In a 16^(th) embodiment of the invention, it is provided that themeasuring tube and the second support element are adapted to react to adisturbance oscillation transmittable externally via the first supportelement, for example, namely via the first support end of the firstsupport element and/or via the second support end of the first supportelement, at the same time to the measuring tube and to the secondsupport element and having a disturbance frequency, for example, adisturbance frequency corresponding to the resonant frequency of thewanted mode, with a parallel oscillation, namely, in each case, with anoscillation not changing a separation between the first and secondsensor components and having, in each case, a frequency corresponding tothe disturbance frequency.

In a 17^(th) embodiment of the invention, it is provided that the firstsupport end of the first support element and the first support end ofthe second support element are rigidly connected with one another,namely in a manner impeding relative movements of the first support endof the first support element and the first support end of the secondsupport element, and that the second support end of the first supportelement and the second support end of the second support element arerigidly connected with one another, namely in a manner impeding relativemovements of the second support end of the first support element and thesecond support end of the second support element.

In an 18^(th) embodiment of the invention, it is provided that the firstsupport end of the first support element is equally rigidly connectedwith the first tube end of the measuring tube as well as with the firstsupport end of the second support element, and that the second supportend of the first support element is equally rigidly connected with thesecond tube end of the measuring tube as well as with the second supportend of the second support element.

In a 19^(th) embodiment of the invention, it is provided that the firstsupport end of the first support element is mechanically connected withthe first tube end of the measuring tube and with the first support endof the second support element in a manner impeding movements of thefirst tube end of the measuring tube relative to the first support endof the second support element, and that the second support end of thefirst support element is mechanically connected with the second tube endof the measuring tube and with the second support end of the secondsupport element in a manner impeding movements of the second tube end ofthe measuring tube relative to the second support end of the secondsupport element.

In a 20^(th) embodiment of the invention, it is provided that themeasuring tube and the second support element extend parallel to oneanother, for example, in such a manner that a minimal separation betweenthe measuring tube and the support element is constant at least over aregion extending between the first oscillation sensor and theoscillation exciter.

In a 21^(st) embodiment of the invention, it is provided that themeasuring tube is at least sectionally S-, respectively Z-shaped and/orat least sectionally straight.

In a 22^(nd) embodiment of the invention, it is provided that the secondsupport element is at least sectionally S-, respectively Z-shaped and/orat least sectionally straight

In a 23^(rd) embodiment of the invention, it is provided that the secondsupport element is formed by means of a cylindrical tube having a tubewall and a lumen surrounded by the tube wall, for example, in such amanner that the lumen of the measuring tube and the lumen of the tubeforming the second support element are equally large, and/or that a wallthickness of the tube wall of the tube forming the second supportelement and the wall thickness of the tube wall of the measuring tubeare equally large.

In a 24^(th) embodiment of the invention, it is provided that themeasuring tube has a symmetry center, relative to which the measuringtube is point symmetric.

In a 25^(th) embodiment of the invention, it is provided that themeasuring tube has a symmetry center, relative to which the measuringtube is point symmetric, and that the second support element likewisehas a symmetry center, relative to which the second support element ispoint symmetric; this, especially, in such a manner that the symmetrycenter of the measuring tube and the symmetry center of the secondsupport element coincide at least in an imaginary projection plane ofthe measuring transducer extending between the measuring tube and thesecond support element, for example, an imaginary projection planeparallel to the measuring tube and/or to the second support element.

In a first further development of the invention, the measuringtransducer further comprises: a second oscillation sensor, for example,an electrodynamic second oscillation sensor and/or a second oscillationsensor constructed equally to the first oscillation sensor, wherein thesecond oscillation sensor has a first sensor component spaced from thefirst sensor component of the first oscillation sensor and affixedexternally on the measuring tube, for example, a first sensor componentconnected with its tube wall by material bonding and/or formed by meansof a permanent magnet and/or constructed equally to the first sensorcomponent of the first oscillation sensor, and the second oscillationsensor has a second sensor component spaced from the second sensorcomponent of the first oscillation sensor and mounted on the secondsupport element, for example, a second sensor component formed by meansof a cylindrical coil and/or constructed equally to the second sensorcomponent of the first oscillation sensor. The second oscillation sensoris, especially, furthermore, adapted to register movements of themeasuring tube relative to the second support element, for example,movements of oscillations of the measuring tube with the wantedfrequency, and to convert such into a second oscillatory signalrepresenting oscillations of the measuring tube, for example, in such amanner that a phase difference between the first and second sensorsignals corresponding to a mass flow rate of a medium flowing in thelumen of the measuring tube is measurable.

In a second further development of the invention, the measuringtransducer further comprises:

a spring element mechanically coupled both with the measuring tube aswell as also with the first support element, for example, a springelement formed by means of a leaf spring, wherein the spring element isadapted, as a result of movement of the measuring tube relative to thefirst support element, to be elastically deformed.

In a third further development of the invention, the measuringtransducer further comprises:

a trimming weight applied on the second support element, for example, ona side of the support element facing away from the measuring tube.

A basic idea of the invention is in the case of measuring transducers ofthe vibration-type to increase their sensitivity to the mass flow rateby features including that, on the one hand, the oscillation exciter isformed by means of exciter components mounted on the measuring tube,respectively on the outer support element, while, on the other hand, theoscillation sensor is formed by means of sensor components mounted onthe measuring tube, respectively on the inner support element, separatedfrom the outer support element. The outer support element is, not leastof all also because of its function as a measuring transducer housing,namely also already in the case of conventional measuring transducers,regularly embodied extremely bending- and twist stiff in comparison tothe measuring tube and can additionally be directly so trimmed that itadditionally also has only resonance frequencies widely remote from theusual wanted frequencies. Thus, the outer support element provides forthe oscillation exciter an almost ideal foundation compared with themeasuring tube, in such a manner that it enables, because of itsextremely small flexibility in comparison to the measuring tube, anefficient, namely ideally exclusive, conversion of mechanical excitationpower delivered by the oscillation exciter into oscillations of themeasuring tube, especially also its wanted oscillations, and,conversely, is not, respectively not mentionably, caused by theoscillation exciter to oscillate. Moreover, additionally also the innersupport element carrying the respective sensor components of each of theoscillation sensors experiences no active exciting of oscillations bythe oscillation exciter, so that, as a result, only the measuring tubeexecutes mentionable oscillations with the wanted frequency, so there,consequently, practically the entire excitation power converted intooscillations with the wanted frequency can deliver an effectivecontribution for generating the Coriolis forces required for measuringthe mass flow rate, respectively the mass flow.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention as well as other advantageous embodiments thereof will nowbe explained in greater detail based on examples of embodiments shown inthe figures of the drawing. Equal parts are provided in all figures withequal reference characters; when perspicuity requires or it otherwiseappears sensible, already presented reference characters are omitted insubsequent figures. Other advantageous embodiments or furtherdevelopments, especially also combinations, first of all, of onlyindividually explained aspects of the invention, result, furthermore,from the figures of the drawing, as well as also the dependent claimsper se. The figures of the drawing show as follows:

FIG. 1 is a perspective side view, especially for application inindustrial measuring- and automation technology, a measuring systemcomprising a measuring transducer of vibration-type in a measuringtransducer housing and a measuring- and operating electronicsaccommodated in an electronics housing secured on the measuringtransducer housing;

FIG. 2 and FIG. 3 are in different perspective side views, an example ofan embodiment of a measuring transducer of vibration-type suitable for ameasuring system according to FIG. 1;

FIG. 4, FIG. 5 and FIG. 6 are different side views of a measuringtransducer of FIG. 2, respectively 3;

FIG. 7 shows schematically, oscillation forms of a measuring tube of ameasuring transducer according to FIG. 2, respectively 3;

FIG. 8 shows schematically, an oscillation form of a measuringtransducer according to FIG. 2, respectively 3; and

FIG. 9 shows schematically, an oscillation form of a measuringtransducer according to FIG. 2, respectively 3.

DETAILED DISCUSSION IN CONJUNCTION WITH THE DRAWINGS

FIGS. 1 to 6 show in different views a measuring system for ascertaininga mass flow, namely a total mass flow during a predeterminable orearlier determined measurement interval and/or a mass flow rate of amedium, especially a liquid or a gas, flowing in a pipeline L onlyschematically illustrated in FIG. 8, respectively 9. The measuringsystem comprises a measuring transducer of vibration-type flowed-throughduring operation by the medium, as well as a measuring- and operatingelectronics ME (shown here only in FIG. 1) for producing measured valuesrepresenting the mass flow rate, respectively the mass flow,respectively for outputting such a measured value as a currently validmeasured value of the measuring system on a corresponding measurementoutput of the measuring- and operating electronics ME.

The measuring- and operating electronics ME, formed e.g. by means of atleast one microprocessor and/or by means of a digital signal processor(DSP), can, such as indicated in FIG. 1, be accommodated in a singleelectronics housing HE of the measuring system.

The measured values X generated by means of the measuring- and operatingelectronics ME can be displayed, for example, on-site, namely directlyat the measuring point formed by means of the measuring system. Forvisualizing measured values internally produced by the measuring systemand/or, in given cases, measuring system internally generated, systemstatus reports, such as, for instance, an error report or an alarm,on-site, the measuring system can, as also indicated by FIG. 1, have,for example, a display- and interaction element HMI communicating withthe measuring- and operating electronics, and can, in given cases, alsobe portable. Thus, the HMI element can be embodied as, for instance, anLCD-, OLED- or TFT display placed behind a window correspondinglyprovided in the electronics housing HE, as well as a corresponding inputkeypad and/or touch screen. In advantageous manner, the measuring- andoperating electronics, for example, also a (re-)programmable-,respectively remotely parameterable, measuring- and operatingelectronics, can additionally be so designed that it can duringoperation of the measuring system exchange with an electronic dataprocessing system, for example, a programmable logic controller (PLC), apersonal computer and/or a work station, superordinated to it, via adata transmission system, for example, a fieldbus system and/orwirelessly per radio, measuring—and/or other operating data, such as,for instance, current measured values, system diagnosis values or,however, also setting values serving for control of the measuringdevice. Furthermore, the measuring- and operating electronics ME can beso designed that it can be fed from an external energy supply, forexample, also via the aforementioned fieldbus system. For the case, inwhich the measuring system is provided for coupling to a fieldbus- orother communication system, the measuring- and operating electronics ME,for example, also a measuring- and operating electronics ME(re-)programmable on-site and/or via a communication system, can have acorresponding communication interface for a data communication,especially conforming to relevant industry standards, e.g. for sendingmeasuring- and/or operating data, for instance, measured valuesrepresenting the mass flow or the mass flow rate, to a programmablelogic controller (PLC) or to a superordinated process control systemand/or for receiving settings data for measuring system. Moreover, themeasuring- and operating electronics ME can have, for example, aninternal energy supply circuit, which is fed during operation via theaforementioned fieldbus system from an external energy supply providedin the aforementioned data processing system. In such case, themeasuring system can be embodied, for example, as a so-calledfour-conductor measuring device, in the case of which the internalenergy supply circuit of the measuring- and operating electronics ME canbe connected with an external energy supply by means of a first pair oflines and the internal communication circuit of the measuring- andoperating electronics ME can be connected with an external dataprocessing circuit or an external data transmission system by means of asecond pair of lines.

The measuring transducer is formed by means of a measuring tube M, whichhas an inlet-side, first tube end M+ and an outlet-side, second tube endM#, a tube wall having a predetermined wall thickness and a lumenextending between the first and second tube ends and surrounded by thetube wall. The measuring tube M is especially adapted, during operationof the measuring system, to guide in its lumen, communicating with alumen of the connected pipeline to form a traversing flow path, aflowing medium, for example, a gas and/or a liquid, and during that tobe caused to oscillate about a static resting position for producingCoriolis forces, wherein the measuring transducer according to anembodiment of the invention, except for the measuring tube M, has no(other) tube, which is adapted to guide a flowing medium in a lumen andduring that to be caused to oscillate about a static resting position.Especially, the measuring tube M is, such as usual in the case ofmeasuring systems of the type being discussed, additionally,furthermore, embodied to be inserted directly into the course of thepipeline L and so, for such purpose, to be connected on an inlet-side tothe first line segment L+ of the pipeline L and on an outlet-side to thesecond line segment L# of the pipeline, such that the lumen of themeasuring tube communicates with a respective lumen of each of the twoline segments L+, L# and a flow path enabling flow from the first linesegment L+, further through the measuring tube M, to the second linesegment L# is formed. The measuring tube M can, such as usual in thecase of such measuring transducers, be manufactured, for example, of ametal tube, for example, a one-piece metal tube of a stainless steel oralso a titanium-, tantalum- and/or a zirconium alloy, and have, forexample, a caliber of greater than 0.5 mm, especially also greater than20 mm.

Besides the measuring tube M, the measuring transducer also comprises afirst support element SE, which with a first support end SE+ ismechanically connected with the tube end M+ of the measuring tube M andwith a second support end SE# with the tube end M# of the measuring tubeM, as well as, laterally spaced from the measuring tube and, forexample, formed by means of a blind tube constructed equally to themeasuring tube M and/or extending at least sectionally parallel to themeasuring tube M, a second support element SS, Which both with a firstsupport end SS+ as well as also with a second support end SS# ismechanically coupled with the support element SE. The support element SEis, among other things, also embodied to be inserted into the course ofthe pipeline L in such a manner that the lumen of the measuring tubecommunicates with a lumen of the pipeline to form the flow path, as wellas to be so connected mechanically with the pipeline that, as a result,the entire measuring transducer MT is held in the pipeline; this,especially, also in such a manner that mechanical loadings, especiallyclamping forces, respectively torques, introduced from the pipeline areabsorbed predominantly by the support element SE and, consequently arekept largely away from the other components of the measuring transducerMT. For connecting support element SE together with the measuring tube Mto the pipeline, such as quite usual in the case of such measuringtransducers, each of the support ends SE+, SE# of the support element SEcan, in each case, have a corresponding connection flange F+,respectively F#, into which, in each case, a corresponding tube end M+,respectively M#, of the measuring tube M opens.

As apparent from FIGS. 2-5, respectively 8 or 9, the measuringtransducer further comprises at least one oscillation exciter Eelectrically connectable to the measuring- and operating electronics MEby means of a pair of connection wires (not shown) and correspondinglyoperable by the measuring- and operating electronics ME, for example,also a single oscillation exciter E, for exciting mechanicaloscillations of the measuring tube M, and, indeed, in such a manner thatthe measuring tube M executes, at least partially, wanted oscillations,namely oscillations suitable for producing Coriolis forces around itsstatic resting position with a wanted frequency, namely a frequencycorresponding to the resonant frequency of a natural oscillatory mode ofthe measuring transducer and referred to in the following as the drive-or also as the wanted mode.

In the example of an embodiment shown in FIGS. 1-6, a correspondingoscillatory length, namely a section of the measuring tube M actuallyexecuting wanted oscillations, extends from the support end SS+ to thesupport end SS# of the support element SS. Especially, in such case,such a natural oscillatory mode of the measuring transducer MT isselected as wanted mode, consequently during operation such resonantoscillations of the measuring transducer MT are excited as wantedoscillations, which have, on the one hand, an as high as possiblesensitivity to the mass flow rate of the flowing medium and whoseresonant frequency, on the other hand, depends also in high measure alsoon a density ρ, typically also a time variable density ρ, of the mediumguided in the measuring tube, and consequently enable a high resolutionof both slight fluctuations of the mass flow rate as well as also slightfluctuations of the density of the medium. In the case of the measuringtransducer shown here, for example, proved as especially suitable forapplication as wanted oscillations of the measuring tube M about animaginary oscillation axis imaginarily connecting its two tube ends M+,M# are bending oscillations, which, such as schematically shown in FIG.7, have over the entire oscillatory length of the measuring tube exactlyfour oscillation nodes, consequently exactly three oscillationantinodes. In an additional embodiment of the invention, the oscillationexciter E is, consequently, adapted to excite as wanted oscillations ofthe measuring tube M such oscillations, which, such as schematicallyshown in FIG. 7, have three oscillation antinodes, and, consequently,four oscillation nodes. The latter lie in at least one imaginaryprojection plane of the measuring transducer on the mentioned imaginaryoscillation axis imaginarily connecting the two tube ends M+, M# withone another.

As a result of Coriolis forces produced by means of the wantedoscillations of the measuring tube flowed-through by the medium, themeasuring tube executes supplementally to the wanted oscillations alsoCoriolis oscillations, namely oscillations about its static restingposition inducible, respectively induced, by Coriolis forces and havinga frequency corresponding to the wanted frequency. Said Coriolisoscillations can correspond, for example, to a natural oscillatory modeequally inherent to the measuring transducer, however, having a resonantfrequency deviating from the resonant frequency of the wanted mode andcausing the measuring tube to execute oscillations, for example, bendingoscillations, about the oscillation axis with, respectively, oneoscillatory antinode and one oscillation node more or, however, also,for instance, for the aforementioned case, in which the wantedoscillations have four oscillation nodes and three oscillationantinodes, with, in each case, one oscillatory antinode and oneoscillation node less than the wanted oscillations.

For registering oscillations of the measuring tube M, not least of allalso the wanted, respectively the Coriolis, oscillations, the measuringtransducer further comprises a first oscillation sensor S1, for example,electrically connectable to the measuring- and operating electronics bymeans of an additional pair of connection wires (not shown), especiallyan electrodynamic, first oscillation sensor S1. The oscillation sensorS1 is, in such case, specially embodied, in order to register movementsof the measuring tube M relative to the support element SS, not least ofall also movements of oscillations of the measuring tube with the wantedfrequency, and to convert such into a first oscillatory signalrepresenting oscillations of the measuring tube. The first oscillatorysignal has, in turn, a signal frequency corresponding to the wantedfrequency. For such purpose, the oscillation sensor S1 includes, such asalso shown schematically in FIG. 3, a first sensor component S1′ affixedexternally on the measuring tube M, for example, connected by materialbonding with its tube wall and/or formed by means of a permanent magnet,as well as a second sensor component S1″ mounted on the support elementSS and formed, for example, by means of a cylindrical coil.

The measuring- and operating electronics ME is not least of all alsoadapted to generate, at least at times, an electrical driver signalcontrolled, for example, to a predetermined voltage level and/or to apredetermined electrical current level for the oscillation exciter E,for example, an electrodynamic oscillation exciter E, namely one formedby means of plunging armature, or solenoid, coils, respectivelyimplemented as an oscillation coil. Thus, the driver signal serves tofeed the oscillation exciter E controllably at least with the electricalpower required for exciting, respectively maintaining, the wantedoscillations, and has, accordingly, a signal frequency corresponding tothe (instantaneous) resonant frequency of the wanted mode, consequentlythe wanted frequency. The oscillation exciter E, in such case, convertsan electrical excitation power fed by means of the electrical driversignal into, e.g. pulsating or harmonic, namely essentially sinusoidal,exciter forces, which act correspondingly on the measuring tube and,thus, actively excite the desired wanted oscillations. For example, thedriver signal can, in such case, simultaneously also have a plurality ofsinusoidal signal components with signal frequencies different from oneanother, of which one, for instance, is, at least at times, as regards asignal power a dominating signal component, which has a signal frequencycorresponding to the wanted frequency. The exciter forces ultimatelygenerated by conversion of electrical excitation power fed into theoscillation exciter E can correspondingly be produced, in such case, inmanner known, per se, to those skilled in the art, namely by means of adriver circuit provided in the measuring- and operating electronics MEand providing the driver signal via an output channel based on signalfrequency and signal amplitude of the at least one sensor signal. Forascertaining the instantaneous resonant frequency of the wanted mode,respectively for tuning the corresponding signal frequency for thedriver signal, there can be provided in the driver circuit, for example,a digital phase control loop (PLL or phase locked loop), while anelectrical current level of the driver signal determinative of amagnitude of the exciter forces can, for example, be set suitably bymeans of a corresponding electrical current controller of the drivercircuit. The measuring- and operating electronics can here also beembodied e.g. to control the driver signal in such a manner that theresonant oscillations have a constant amplitude, consequently are alsolargely independent of the density ρ, respectively also the viscosity ηof the respective medium to be measured. The construction andapplication of the aforementioned phase control-loop for the activeexciting of vibratory elements of the type being discussed to aninstantaneous resonant frequency is described at length e.g. in U.S.Pat. No. 4,801,897. Of course, also other driver circuits known, per se,to those skilled in the art, for example, also from the above mentionedU.S. Pat. No. 4,801,897, U.S. Pat. No. 5,024,104, respectively U.S. Pat.No. 6,311,136, to be suitable for tuning the exciter energy,respectively the excitation power, can be used. Moreover, the measuring-and operating electronics can, furthermore, be adapted to measure adensity and/or a viscosity of the medium, for instance, based on theoscillatory signal and/or based on the driver signal.

In order to achieve an as efficient as possible converting of themechanical excitation power provided by the oscillation exciter into thewanted oscillations of the measuring tube, consequently also itsCoriolis oscillations, in the case of the measuring transducer of theinvention, the oscillation exciter E is formed, as well as evident alsofrom FIGS. 2-5, respectively 8, by means of a first exciter component E′affixed externally on the measuring tube M, for example, also connectedwith its tube wall by material bonding, as well as by means of a secondexciter component E″ mounted on the support element SE, here namelyplaced on an inside of the support element SE facing the measuring tube.The efficiency, with which the wanted-, respectively Coriolis,oscillations are excitable, is, in such case improved in that, as wellas also schematically shown in FIG. 8, by means of the so formedoscillation exciter, in contrast to conventional measuring transducersof the type being discussed, practically no mentionable excitation poweris converted into oscillations of the support element SS, which are,indeed, registerable by the oscillation sensor S1, but, however, canlastly provide no contribution to the Coriolis oscillations of themeasuring tube required for the mass flow measurement. For the case, inwhich the oscillation exciter E is an electrodynamic oscillationexciter, the exciter component E′ can be formed, for example, by meansof a permanent magnet and the exciter component E″ by means of acylindrical coil complementary to the permanent magnet. In an additionalembodiment of the invention, it is, in such case, further provided thatthe measuring transducer has, such as also evident from a combination ofFIGS. 2-5, except for the oscillation exciter E, no other oscillationexciter with exciter components mounted on the support element SE,respectively on the support element SS.

Although a registering of the wanted-, as well as also the Coriolis,oscillations, consequently a measuring of the mass flow rate,respectively of the mass flow, can be accomplished basically also bymeans of only one oscillation sensor, for example, by a phasemeasurement between the exciter signal driving the oscillation exciter Eand the sensor signal delivered by the oscillation sensor S1, accordingto an additional embodiment of the invention, in the case of themeasuring transducer of the invention, a second oscillation sensor S2,for example, again, an electrodynamic, second oscillation sensor S2,respectively a second oscillation sensor S2 constructed equally to thefirst oscillation sensor S1, is provided. This oscillation sensorincludes, such as directly evident from a combination of FIGS. 3 and 5,a first sensor component S2′ spaced from the sensor component S1′ of theoscillation sensor S1 and affixed externally on the measuring tube M,for example, namely also one by formed means of a permanent magnetand/or constructed equally to the sensor component of the firstoscillation sensor, as well as a second sensor component S2″ spaced fromthe second sensor component S1″ of the oscillation sensor S1 and mountedon the support element SS, for example, one formed by means of acylindrical coil and/or constructed equally to the sensor component S1″of the oscillation sensor S1.

Equally as in the case of the oscillation sensor S1, also theoscillation sensor S2 is adapted to register movements of the measuringtube M relative to the support element SS, for instance, also movementsof oscillations of the measuring tube M with the wanted frequency, andto convert such into a second oscillatory signal representingoscillations of the measuring tube M, and having a signal frequencycorresponding to the wanted frequency, consequently also equal to thesignal frequency of the first oscillation signal; this, especially, alsoin such a manner that between the first and second sensor signals,corresponding to a mass flow rate of a medium flowing in the lumen ofthe measuring tube, a phase difference is measurable, based on whichthus the measuring- and operating electronics ME can ascertain the massflow rate, respectively the mass flow, of the medium. According to anadditional embodiment of the invention, it is, furthermore, providedthat the measuring transducer MT has except for the first and secondoscillation sensors S1, S2 no (additional) oscillation sensor with asensor component mounted on the support element SS.

The measuring tube M is according to an additional embodiment of theinvention, and as directly evident from the combination of FIGS. 2 and 3and 4, embodied point symmetrically relative to a symmetry center ZM,and can, consequently, be, for example, straight, or at least in amiddle section, also S-, respectively Z-shaped, in given cases, also insuch a manner that, as evident also from FIG. 4, alternately arc shapedtube sections and straight tube sections are arranged serially followingone another. This has, among other things, the advantage that, for thecase, in which oscillations of the measuring tube with three oscillationantinodes serve as wanted oscillations, the measuring transducer can,such as already presented in the above mentioned U.S. Pat. No.7,077,014, also be so embodied that the wanted oscillations of themeasuring tube produce no, or at least no mentionable, transverseforces, even in the case of density changing in considerable measure asa function of time, so that no associated disturbances of the Coriolisoscillations need to be cared for.

For additionally improving the oscillatory behavior, not least of allalso for additional lessening of the aforementioned transverse forces,the measuring transducer, according to another embodiment of theinvention, is supplementally equipped with a spring element C, which ismechanically coupled both with the measuring tube as well as also withthe first support element, in such a manner that the spring element iselastically deformed during operation as result of a movement of themeasuring tube relative to the first support element. For such purpose,the spring element is mechanically connected with a first end C+ withthe measuring tube M, for example, at a securement point c′ lying on animaginary circularly shaped peripheral line of the measuring tube Mimaginarily contacting also the first exciter component E′, and with asecond end C# with the support element SE, for example, at a securementpoint c″ laterally spaced from the second exciter component E″. In suchcase, the first end C+ of the spring element C and the measuring tube Mare connected with one another as rigidly as possible, namely in amanner excluding relative movements of the end C+ and the measuringtube, respectively the second end C# of the spring element C and thesupport element SE are connected with one another as rigidly aspossible, namely in a manner excluding relative movements of the end andthe support element SE. The spring element C can be formed, for example,by means of a helical spring or, however, also, such as directly evidentfrom a combination of FIGS. 2-5, by means of a leaf spring, which isconnected with the measuring tube by means of a first holder affixed bymaterial bonding to the measuring tube to form the securement point c′and with the support element SE by means of a rod-shaped second holderaffixed by material bonding to the support element SE to form thesecurement point c″. As already shown in the above mentioned U.S. Pat.No. 7,077,014, the measuring transducer MT can also be additionallytrimmed by means of the spring element C in such a manner that, asresult, as also symbolized in FIG. 7 by the continuous line, thetransverse forces developed by the wanted oscillations of the measuringtube can completely neutralize one another, so that the measuringtransducer MT no longer produces mentionable transverse forces, whichcould be transmitted to the connected pipeline.

Particularly for the case, in which the support element SS is embodiedas a blind tube, the support element SS and the measuring tube M are,such as also directly evident from a combination of FIGS. 2-6,advantageously embodied essentially with equal construction, at least asregards their outer contours, as much as possible, however, also asregards all dimensions, respectively also as regards the materials fromwhich they are, respectively, produced. In accordance therewith, alsothe support element SS has, same as the measuring tube M, according toan additional embodiment of the invention a symmetry center ZSS,relative to which also the support element SS is point symmetric.Measuring tube M and support element SS are, in advantageous manner,furthermore, both in such a manner point symmetrically embodied and soarranged that, such as also directly evident from the combination ofFIGS. 4 and 5, the symmetry center ZM of the measuring tube M and thesymmetry center ZSS of the support element SS coincide at least in animaginary projection plane PE of the measuring transducer extendingbetween the measuring tube M and the support element SS, especiallyparallel to the measuring tube M and/or to the support element SS, sothat, consequently, an inner part of the measuring transducer formed bymeans of measuring tube M and support element SS is likewise pointsymmetric relative to a symmetry center lying in the imaginaryprojection plane PE. In an additional embodiment of the invention, thesupport element SS is additionally formed by means of a blind tubeextending at least sectionally parallel to the measuring tube M, namelya tube not flowed through by the medium to be measured, in such a mannerthat, as also directly evident from FIG. 5, respectively 6, a minimumseparation between the measuring tube and the support element isconstant at least over a region extending between the first oscillationsensor and the oscillation exciter. In another embodiment of theinvention, both the measuring tube as well as also the support elementSS are at least sectionally S-, respectively Z-shaped and/or at leastsectionally straight; this, especially, in such a manner that, asdirectly evident from a combination of FIGS. 2-6, measuring tube M andsupport element SS are of equal construction, at least as regards theirouter contours, especially, however, also as regards the respectivelyused materials and/or as regards their total geometry. In accordancetherewith, the support element SS can in simple manner also be formede.g. by means of a cylindrical tube having a tube wall and a lumensurrounded by the tube wall, for instance, also in such a manner thatthe lumen of the measuring tube M and the lumen of the tube forming thesupport element SS are equally large, and/or that a wall thickness ofthe tube wall of the tube forming the support element SS and the wallthickness of the tube wall of the measuring tube M are equally large.Consequently, measuring tube M and support element SS can be produced bymeans of two essentially equal tubes.

The support element SE includes in the example of an embodiment shownhere, furthermore, a first endpiece SE′ forming the first support endSE+ and formed, for example, by means of a plate or a funnel, a secondendpiece SE″ forming the second support end SE# and formed, for example,by means of a plate or a funnel, as well as an intermediate piece SE′″,especially a cylindrical and/or tubular intermediate piece SE′″,extending between the two, ideally equally constructed, endpieces SE′,SE″. The intermediate piece SE″, consequently the support element SEmanufactured therewith, can, such as shown here in the example of anembodiment, accordingly also be formed by means of a hollow body, herein at least sectionally cylindrical, respectively tubular, form, forexample, in such a manner that the support element SE formed by means ofa ideally cylindrical tube having a tube wall, especially a metal tubewall, for example, of steel, as well as a lumen surrounded by the tubewall, at least partially encases both the measuring tube M as well asalso the support element SS, and, consequently, has a lumen, throughwhich both the measuring tube M as well as also the support element SSat least partially extend. In the case of a comparatively widelyeccentric measuring tube M, respectively support element SS, namely acurved measuring tube M, respectively support element SS, protrudinglaterally of the support element SE, then obviously correspondinglateral openings for the measuring tube M, respectively support elementSS, are provided in a side wall of such a tube body serving as supportelement SE. Support element SE can—such as quite usual in the case ofsuch components of measuring transducers of the type being discussed—beproduced, for example, of a stainless steel.

Support element SE can serve, furthermore, when correspondingly at leastsectionally cylindrical, as a housing of the measuring transducerjacketing the measuring tube and support element SS together, in givencases, completed by means of corresponding housing caps for the possiblylaterally protruding sections of the measuring tube M and supportelement SS. The support element SE can, however, also be embodied, suchas directly evident from a combination of FIGS. 1-6, as an independentcomponent of the measuring transducer MT and be directly manufacturablee.g. also from a comparatively cost effective, free machining- orstructural steel, so that it together with the other components of themeasuring transducer, especially also the measuring tube M and thesupport element SS, can be accommodated in a measuring transducerhousing HT likewise formed as a separate component of the measuringtransducer MT and serving here principally as a protective shell forhermetically sealing the interior of the measuring transducer MT fromthe surrounding atmosphere and, in given cases, also providing pressure-and/or explosion resistance. The measuring transducer housing HT can bemanufactured, for example, of a smooth or also corrugated, stainlesssteel sheet or also a synthetic material, e.g. a plastic. Furthermore,the measuring transducer housing HT can, as also indicated in FIG. 1,have a connection nozzle, on which the electronics housing HE is mountedso as to form a measuring device of compact construction. Within theconnection nozzles can be arranged, furthermore, a hermetically sealedand/or pressure resistant feedthrough manufactured, for example, bymeans of glass- and/or plastic potting compound, for electricalconnection wires extending between the measuring- and operatingelectronics and the measuring transducer. The measuring transducerhousing HT can, such as directly evident from a combination of FIGS. 2,4 and 6, for instance, for the purpose of providing an as small aspossible installed volume, on the one hand, and an as optimal aspossible exploitation of the installed volume, on the other hand, beadditionally so arranged relative to the support element SE that alongitudinal axis corresponding to a symmetry axis of the measuringtransducer housing HT is inclined relative to a longitudinal axiscorresponding to a principle axis of inertia of the support element SEby an angle, which is greater than 0° and less than 10°.

Measuring transducers of the type being discussed, consequently alsothose of the invention, have a plurality of natural disturbance modes,each with a resonant frequency, namely such oscillation modes, whoseexciting during operation actually is not desired, since they wouldotherwise disturb the wanted oscillations, respectively the at least oneoscillation signal. Of special interest in the case of the measuringtransducer of the invention are also those oscillation modes, in thefollowing referred to as disturbance modes of first type, in which thesupport element SE can, in each case, execute disturbing oscillations,namely, in each case, oscillations around its static resting position,effecting movements relative to measuring tube, as well as thoseoscillation modes, in the following referred to as disturbance modes ofsecond type, in which the second support element can execute, in eachcase, disturbing oscillations, namely, in each case, oscillationseffecting movements relative to measuring tube about its static restingposition. For preventing an actually undesired exciting also of thedisturbance modes by means of the oscillation exciter E, the measuringtransducer is, according to an additional embodiment of the invention,furthermore so embodied that the resonant frequencies of each of thedisturbance modes of first type as well as also each of the disturbancemodes of second type deviates as durably as possible from the resonantfrequency of the wanted mode, especially also by, in each case, morethan 2 Hz.

In such case, it is, furthermore, to be taken into consideration, that,on the other hand, the resonant frequency of the wanted mode,consequently the wanted frequency, is, not least of all as result oftime changes of the density of the medium flowing in the lumen of themeasuring tube during operation of the measuring transducer, variablenaturally within a wanted frequency interval extending, depending onapplication, over some tens or even some hundreds of hertz. Said wantedfrequency interval has, in such case, a lower interval boundary, definedby a least frequency value not subceeded by the wanted frequency, aswell as also an upper interval boundary, defined by a greatest frequencyvalue not exceeded by the wanted frequency. The size of the wantedfrequency interval, respectively the placing of its interval boundaries,is, in such case, determined both by the mechanical construction of themeasuring transducer as well as also by the medium to be measured,consequently by the application in which the measuring transducerserves.

Particularly for the case, in which the support element SS isessentially of equal construction to the measuring tube M, the measuringtransducer has, among other things, also a first disturbance mode ofsecond type, which is similar to the wanted mode, in that the secondsupport element can execute disturbing oscillations, which have exactlyas many oscillation antinodes and oscillation nodes as the wantedoscillations of the measuring tube. For the purpose of preventing anundesired exciting of disturbance modes of second type, according to anadditional embodiment of the invention, the measuring transducer is soembodied that the first disturbance mode of second type has a resonantfrequency, which is as durably as possible, respectively always, less,especially by more than 2 Hz, than the resonant frequency of the wantedmode, consequently is correspondingly less than the lower intervalboundary of the wanted frequency interval. This can be achieved, on theone hand, by means of the already mentioned spring element C, whichincreases the resonant frequency of the wanted mode, consequently alsothe interval boundaries of the wanted frequency interval. Alternativelyor supplementally, however, also the resonant frequency of the firstdisturbance mode of second type can be further decreased, consequentlythe separation from the lower interval boundary of the wanted frequencyinterval can be increased, when, such as also schematically shown inFIGS. 4 and 5, a trimming weight W, virtually acting as a point mass, ismounted on the support element SS, for example, on a side of the supportelement SS facing away from the measuring tube. The effect of thetrimming weight W in decreasing the resonant frequency of the firstdisturbance mode of second type can, in such case, be optimized byproviding that the mass provided by the trimming weight W acts as muchas possible at a site of maximum oscillation amplitude of theoscillations of the support element SS, for example, thus, such asschematically indicated in FIG. 4, in a central section of the supportelement SS, respectively a section of the support element SS lyingopposite the oscillation exciter E.

In the case of adjusting measuring tube M and support element SS asregards the interval boundaries of the wanted frequency interval,respectively the resonant frequency of the first disturbance mode ofsecond type, it is, furthermore, to be taken into consideration that themeasuring transducer also has a second disturbance mode of second type,in which the second support element can execute such disturbingoscillations, which have one oscillatory antinode more, consequently oneoscillation node more, than the wanted oscillations of the measuringtube. In an additional embodiment of the invention, it is, furthermore,provided that measuring tube M and support element SS are so matched toone another that resonant frequencies of the second disturbance modes ofsecond type are more, especially more than 2 Hz, than the upper intervalboundary of the wanted frequency interval, consequently durably morethan the wanted frequency. As a result of this, thus the support elementSS can at no point in time execute resonant oscillations with a resonantfrequency corresponding to the wanted frequency, respectively thesupport element SS can, at most, execute resonant oscillations, whichhave resonant frequencies always deviating from the wanted frequency.

In an additional embodiment of the invention, measuring tube M andsupport element SE are so embodied matched to one another that thesupport element SE has a maximum flexibility, which is less than amaximum flexibility of the measuring tube. In another embodiment of theinvention, additionally also the support element SS and the supportelement SE are so embodied matched to one another that the supportelement SE has a maximum flexibility, which is less than a maximumflexibility of the support element SS, so that thus, conversely, thesupport element SE is in comparison to the measuring tube M and supportelement SS significantly stiffer, especially significantly more bending-and twist resistant. This can for the above-described case, in which thesupport element SE is formed by means of a tube having a tube wall and alumen surrounded by the tube wall be very simply implemented byproviding that a wall thickness of the tube wall of the tube forming thefirst support element SE is greater than the wall thickness of the tubewall of the measuring tube (typically approximately more than 0.5 mm andless than 3 mm); this, especially, in such a manner that the wallthickness of the tube wall of the tube forming the first supportelement, amounting as much as possible to more than 3 mm, is more thantwice as great as the wall thickness of the tube wall of the measuringtube M.

As already mentioned, measuring transducers of vibration-type with onlya single curved or straight measuring tube can have, at times, increasedmeasuring errors, even though the measuring transducer is almost ideallybalanced over a significant wanted frequency interval, namely can beoperated without producing mentionable undesired transverse forces asresult of density changing with time. Such measuring errors can beattributed, among other things, also to the fact that the measuring tubeM and the support element SS, consequently components of the measuringtransducer carrying each of the two sensor components of one and thesame oscillation sensor, react differently to a disturbance transferredfrom the connected pipeline to the support element SE, respectively themeasuring transducer housing HT possibly formed therewith, for example,a disturbance in the form of a vibration of the pipeline with afrequency corresponding to the wanted frequency. Thus, measuringtransducers of the type being discussed have, at times, a mechanicalcommon-mode suppression insufficient for the desired accuracy ofmeasurement. This is not least of all due to the fact that in the caseof conventional measuring transducers the measuring tube M is typicallycoupled to the support element SE differently than to the supportelement SS. In an additional embodiment of the invention, it is,consequently, furthermore provided that both the tube end M+ as well asalso the support end SS+ are mechanically connected with the support endSE+ and both the tube end M# as well as also the support end SS# aremechanically connected with the support end SE#. This is provided,especially, in such a manner that the tube end M+ is connected rigidlywith the support end SE+, namely in a manner excluding relativemovements between tube end M+ and corresponding support end SE+, and thetube end M# is connected rigidly with the support end SE#, namely in amanner excluding relative movements between tube end M# andcorresponding support end SE#, and the support end SS+ is connectedrigidly with the support end SE+, namely in a manner excluding relativemovements between support end SS+ and corresponding support end SE+, andthe support end SS# is connected rigidly with the support end SE#,namely in a manner excluding relative movements between support end SS #and corresponding support end SE#. Ideally, in such case, the supportend SE+ is equally rigidly connected with the corresponding tube end M+as well as with the corresponding support end SS+, respectively thesupport end SE# is equally rigidly connected with the corresponding tubeend M# as well as with the corresponding support end SS#. As a result ofsuch a coupling of measuring tube M and support element SS with thesupport element SE, namely the measuring tube M and the support elementSS can, such as schematically shown in FIG. 9, react to a disturbanceoscillation transmittable externally via support element SE, forexample, via support end SE+ and/or via support end SE#, at the sametime to measuring tube M and support element SS, and having adisturbance frequency, with a parallel oscillation not damaging for themeasuring of the mass flow rate, namely, in each case, with anoscillation not changing a separation between the two sensor componentsS1′, S1″ and having, in each case, a frequency corresponding to thedisturbance frequency; this not least of all also for the case, in whichthe disturbance frequency corresponds to the resonant frequency of thewanted mode, consequently the wanted frequency. Depending on type,respectively action direction, of the disturbance introduced, in eachcase, into the measuring transducer, the parallel oscillation can haveone or more oscillation antinodes, for example, also, such as shown inFIG. 9 only by way of example, two oscillation antinodes. Associatedtherewith, both the measuring tube and the support element SS can, ineach case, also assume an oscillation form corresponding to the Coriolisoscillations, without this influencing the oscillatory signal.

The invention claimed is:
 1. A measuring transducer for a Coriolis massflow measuring device, which measuring transducer comprises: a measuringtube exhibiting an inlet-side, first tube end and an outlet-side, secondtube end, said measuring tube including a tube wall exhibiting apredetermined wall thickness and a lumen surrounded by the tube wall andextending between said first and said second tube ends, said measuringtube being adapted to guide a flowing medium in its lumen, and duringthat to be caused to oscillate about a static resting position forproducing Coriolis forces; a first support element, wherein said firstsupport element is with a first support end connected mechanically, withsaid first tube end of said measuring tube and with a second support endconnected mechanically, with said second tube end of said measuringtube; a second support element, wherein said second support element islaterally spaced from said measuring tube and is mechanically coupledwith said first support element both with a first support end as well asalso with a second support end; an oscillation exciter, including afirst exciter component affixed externally on said measuring tube, andincluding a second exciter component mounted on the first supportelement; at least a first oscillation sensor, including a first sensorcomponent externally affixed to said measuring tube, and a second sensorcomponent mounted on second support element, wherein: the measuringtransducer exhibits a wanted mode, namely an oscillatory mode, in whichsaid measuring tube can execute wanted oscillations, namely oscillationsabout its static resting position suitable for producing Coriolis forceswith a wanted frequency, namely a frequency corresponding to a resonantfrequency of the wanted mode; said oscillation exciter is adapted toexcite the wanted oscillations of said measuring tube; and said firstoscillation sensor is adapted to register movements of said measuringtube relative to said second support element, and to convert such into afirst oscillatory signal representing oscillations of said measuringtube.
 2. The measuring transducer as claimed in claim 1, wherein: saidfirst support end of said second support element is mechanicallyconnected, with said first support end of said first support element;and said second support end of said second support element ismechanically connected, with said second support end of said firstsupport element.
 3. The measuring transducer as claimed in claim 1,wherein: said measuring transducer, except for said oscillation exciter,has no exciter component mounted on said first support element, and/orsaid measuring transducer has no oscillation exciter with an excitercomponent mounted on said second support element.
 4. The measuringtransducer as claimed in claim 1, wherein: said first support element isadapted to be inserted into the course of a pipeline in such a mannerthat said lumen of the measuring tube communicates with a lumen of saidpipeline to form a flow path.
 5. The measuring transducer as claimed inclaim 1, wherein: said first support end of said first support elementhas a connecting flange, into which said first tube end of saidmeasuring tube opens; and said second support end of said first supportelement has a connecting flange, into which said second tube end of saidmeasuring tube opens.
 6. The measuring transducer as claimed in claim 1,wherein: said first support element is formed by means of a hollow body.7. The measuring transducer as claimed in claim 1, wherein: said firstsupport element exhibits a lumen, through which both said measuring tubeas well as also said second support element extend.
 8. The measuringtransducer as claimed in claim 1, wherein: said first support elementincludes a first endpiece forming said first support end, a secondendpiece forming said second support end, as well as an intermediatepiece, extending between said two endpieces.
 9. The measuring transduceras claimed in claim 1, wherein: said first support element exhibits amaximum flexibility, which is less than a maximum flexibility of saidmeasuring tube.
 10. The measuring transducer as claimed in claim 1,wherein: said first support element exhibits a maximum flexibility,which is less than a maximum flexibility of said second support element.11. The measuring transducer as claimed in claim 1, wherein: said firstsupport element is formed by means of a cylindrical tube including atube wall and a lumen surrounded by the tube wall.
 12. The measuringtransducer as claimed in claim 11, wherein: a wall thickness of saidtube wall of said tube forming said first support element is greaterthan the wall thickness of said tube wall of said measuring tube. 13.The measuring transducer as claimed in claim 1, wherein: the measuringtransducer, except for said measuring tube, has no tube, which isadapted to guide a medium flowing in a lumen and during that to becaused to oscillate about a static resting position.
 14. The measuringtransducer as claimed in claim 1, further comprising: a secondoscillation sensor, including a first sensor component spaced from saidfirst sensor component of said first oscillation sensor and affixedexternally on said measuring tube, and including a second sensorcomponent spaced from said second sensor component of said firstoscillation sensor and mounted on said second support element.
 15. Themeasuring transducer as claimed in claim 14, wherein: the measuringtransducer has, except for said first and said second oscillationsensors no oscillation sensor with a sensor component mounted on saidsecond support element; and/or said second oscillation sensor is adaptedto register movements of said measuring tube relative to said secondsupport element, and to convert such into a second oscillatory signalrepresenting oscillations of said measuring tube.
 16. The measuringtransducer as claimed in claim 1, wherein: the resonant frequency of thewanted mode depends on a density, of the medium guided in the measuringtube.
 17. The measuring transducer as claimed in claim 1, wherein: themeasuring transducer exhibits a plurality of disturbance modes of thefirst type exhibiting, in each case, a resonant frequency, namelyoscillation modes, in which said first support element can, in eachcase, execute disturbing oscillations, namely, in each case,oscillations effecting movements about its static resting positionrelative to said measuring tube, as well as a plurality of disturbancemodes of the second type exhibiting, in each case, a resonant frequency,namely oscillation modes, in which said second support element can, ineach case, execute disturbing oscillations, namely, in each case,oscillations effecting movements about its static resting positionrelative to said measuring tube; and the resonant frequencies both ofeach of the disturbance modes of the first type as well as also each ofthe disturbance modes of the second type deviates, from the resonantfrequency of the wanted mode, by more than 2 Hz.
 18. The measuringtransducer as claimed in claim 17, wherein: the measuring transducerexhibits a first disturbance mode of the second type, which is similarto the wanted mode and in which said second support element can executesuch disturbing oscillations, which have exactly as many oscillationantinodes and oscillation nodes as the wanted oscillations of saidmeasuring tube.
 19. The measuring transducer as claimed in claim 18,wherein: said first disturbance mode of the second type exhibits aresonant frequency, which is less, than the resonant frequency of thewanted mode.
 20. The measuring transducer as claimed in claim 1,wherein: the wanted frequency is, variable within a wanted frequencyinterval.
 21. The measuring transducer as claimed in claim 18, wherein:said wanted frequency interval has a lower interval boundary, defined bya smallest frequency value not subceeded by the wanted frequency; andsaid first disturbance mode of the second type has a resonant frequency,which is less than, the lower interval boundary of said wanted frequencyinterval.
 22. The measuring transducer as claimed in claim 21, wherein:the measuring transducer exhibits a second disturbance mode of thesecond type, in which said second support element can execute disturbingoscillations, which have one oscillatory antinode more, consequently oneoscillation node more, than the wanted oscillations of said measuringtube; said wanted frequency interval has an upper interval boundary,defined by a greatest frequency value not exceeded by said wantedfrequency; and said second disturbance mode of the second type has aresonant frequency, which is greater, than the upper interval boundaryof said wanted frequency interval.
 23. The measuring transducer asclaimed in claim 1, wherein: said wanted oscillations of said measuringtube exhibit four, oscillation nodes, respectively three, oscillationantinodes.
 24. The measuring transducer as claimed in claim 22, wherein:the measuring transducer exhibits a third disturbance mode of the secondtype, in which said second support element can execute disturbingoscillations, which have one oscillatory antinode less, consequently oneoscillation node less, than the wanted oscillations of said measuringtube; and said third disturbance mode of the second type has a resonantfrequency, which is less, than the lower interval boundary of saidwanted frequency interval.
 25. The measuring transducer as claimed inclaim 1, further comprising: a spring element mechanically coupled bothwith said measuring tube as well as also with said first supportelement, wherein said spring element is adapted to be elasticallydeformed as result of movement of said measuring tube relative to saidfirst support element.
 26. The measuring transducer as claimed in claim25, wherein: said spring element includes a first end connected withsaid measuring tube.
 27. The measuring transducer as claimed in claim26, wherein: said spring element includes a second end connected withsaid first support element.
 28. The measuring transducer as claimed inclaim 1, further comprising: a trimming weight applied on said secondsupport element.
 29. The measuring transducer as claimed in claim 1,wherein: said measuring tube and said second support element are adaptedto react to a disturbance oscillation transmittable externally via saidfirst support element, with a parallel oscillation, namely, in eachcase, with an oscillation not changing a separation between said firstand said second sensor components and exhibiting, in each case, afrequency corresponding to the said disturbance frequency.
 30. Themeasuring transducer as claimed in claim 1, wherein: said first supportend of said first support element and said first support end of saidsecond support element are rigidly connected with one another, namely ina manner impeding relative movements of said first support end of saidfirst support element and said first support end of said second supportelement; and said second support end of said first support element andsaid second support end of said second support element are rigidlyconnected with one another, namely in a manner impeding relativemovements of said second support end of said first support element andsaid second support end of said second support element.
 31. Themeasuring transducer as claimed in claim 1, wherein: said first supportend of said first support element is equally rigidly connected with saidfirst tube end of said measuring tube as well as with said first supportend of said second support element; and said second support end of saidfirst support element is equally rigidly connected with said second tubeend of said measuring tube as well as with said second support end ofsaid second support element.
 32. The measuring transducer as claimed inclaim 1, wherein: said first support end of said first support elementis mechanically connected with said first tube end of said measuringtube and with said first support end of said second support element in amanner impeding movements of said first tube end of said measuring tuberelative to said first support end of said second support element; andsaid second support end of said first support element is mechanicallyconnected with said second tube end of said measuring tube and with saidsecond support end of said second support element in a manner impedingmovements of said second tube end of said measuring tube relative tosaid second support end of said second support element.
 33. Themeasuring transducer as claimed in claim 1, wherein: said measuring tubeand said second support element extend parallel to one another; and/orsaid measuring tube is at least sectionally S-, respectively Z-shapedand/or at least sectionally straight; and/or said second support elementis at least sectionally S-, respectively Z-shaped and/or at leastsectionally straight; and/or said second support element is formed bymeans of a cylindrical tube having a tube wall and a lumen surrounded bythe tube wall.
 34. The measuring transducer as claimed in claim 1,wherein: said measuring tube shows a symmetry center, relative to whichsaid measuring tube is point symmetric.
 35. The measuring transducer asclaimed in claim 34, wherein: said second support element shows asymmetry center, relative to which said second support element is pointsymmetric.
 36. The measuring transducer as claimed in claim 35, wherein:the symmetry center of said measuring tube and the symmetry center ofsaid second support element coincide at least in an imaginary projectionplane of the measuring transducer extending between said measuring tubeand said second support element.
 37. A measuring system, comprising: ameasuring transducer, for a measuring transducer for a Coriolis massflow measuring device as well as a measuring- and operating electronicselectrically connected to the measuring transducer, which measuringtransducer comprises: a measuring tube exhibiting an inlet-side, firsttube end and an outlet-side, second tube end, said measuring tubeincluding a tube wall exhibiting a predetermined wall thickness and alumen surrounded by the tube wall and extending between said first andsaid second tube ends, and said measuring tube being adapted to guide aflowing medium in its lumen, and during that to be caused to oscillateabout a static resting position for producing Coriolis forces; a firstsupport element, wherein said first support element is with a firstsupport end connected mechanically, with said first tube end of saidmeasuring tube and with a second support end connected mechanically,with said second tube end of said measuring tube; a second supportelement, wherein said second support element is laterally spaced fromsaid measuring tube and is mechanically coupled with said first supportelement both with a first support end as well as also with a secondsupport end; an oscillation exciter, including a first exciter componentaffixed externally on said measuring tube, and including a a secondexciter component mounted on the first support element; at least a firstoscillation sensor, including a first sensor component externallyaffixed to said measuring tube, and a second sensor component mounted onsecond support element, wherein: the measuring transducer exhibits awanted mode exhibiting a resonant frequency, namely an oscillatory mode,in which said measuring tube can execute wanted oscillations, namelyoscillations about its static resting position suitable for producingCoriolis forces and exhibiting a wanted frequency, namely a frequencycorresponding to the resonant frequency of the wanted mode; saidoscillation exciter is adapted to excite the wanted oscillations of saidmeasuring tube; and said first oscillation sensor is adapted to registermovements of said measuring tube relative to said second supportelement, and to convert such into a first oscillatory signalrepresenting oscillations of said measuring tube.
 38. The measuringtransducer as claimed in claim 1, wherein: the first support element isat least sectionally cylindrical.
 39. The measuring transducer asclaimed in claim 1, wherein: the first support element is embodied as ahousing jacketing said measuring tube.
 40. The measuring transducer asclaimed in claim 1, wherein: the second support element is formed bymeans of a blind tube constructed equally to said measuring tube. 41.The measuring transducer as claimed in claim 1, wherein: the secondsupport element extends at least sectionally parallel to said measuringtube.
 42. The measuring transducer as claimed in claim 6, wherein: thehollow body forming said first support element is at least sectionallycylindrical.
 43. The measuring transducer as claimed in claim 6,wherein: the hollow body forming said first support element is tubular.44. The measuring transducer as claimed in claim 6, wherein: the hollowbodyforming said first support element at least partially envelops bothsaid measuring tube as well as also said second support element.
 45. Themeasuring transducer as claimed in claim 8, wherein: said intermediatepiece is cylindrical.
 46. The measuring transducer as claimed in claim8, wherein: said intermediate piece is tubular.
 47. The measuringtransducer as claimed in claim 8, wherein: said intermediate piece formsa hollow body at least partially enveloping both said measuring tube aswell as also said second support element.
 48. The measuring transduceras claimed in claim 11, wherein: said measuring tube and said secondsupport element are, in each case, arranged, at least partially, withina lumen of said tube forming the first support element.
 49. Themeasuring transducer as claimed in claim 11, wherein: a wall thicknessof the tube wall forming said first support element tube is greater thanthe wall thickness of said tube wall of the measuring tube.
 50. Themeasuring transducer as claimed in claim 1, wherein: said first supportend of said second support element is rigidly connected with said firstsupport end of said first support element; and said second support endof said second support element is rigidly connected with said secondsupport end of said first support element.
 51. The measuring transduceras claimed in claim 12, wherein: the wall thickness of said tube wall ofsaid tube forming said first support element is greater than twice aslarge as the wall thickness of said tube wall of said measuring tube.52. The measuring transducer as claimed in claim 12, wherein: the wallthickness of said tube wall of said measuring tube is greater than 0.5mm and less than 3 mm and the wall thickness of said tube wall of saidtube forming said first support element is greater than 3 mm.
 53. Themeasuring transducer as claimed in claim 1, wherein: said first supportelement is formed by means of a hollow body at least partiallyenveloping both said measuring tube as well as also said second supportelement.
 54. The measuring transducer as claimed in claim 21, wherein:the resonant frequency of said second disturbance mode of the secondtype is less than the lower interval boundary of said wanted frequencyinterval by more than 2 Hz.
 55. The measuring transducer as claimed inclaim 22, wherein: the resonant frequency of said second disturbancemode of the second type is greater than the upper interval boundary ofsaid wanted frequency interval by more than 2 Hz.
 56. The measuringtransducer as claimed in claim 1, wherein: said wanted oscillations ofsaid measuring tube exhibit exactly four oscillation nodes, respectivelyexactly three oscillation antinodes.